0000000000122061

AUTHOR

Nina Galinina

showing 17 related works from this author

The inefficient aerobic energetics ofZymomonas mobilis: Identifying the bottleneck

2014

To investigate the mechanisms of Zymomonas mobilis uncoupled aerobic metabolism, growth properties of the wild-type strain Zm6 were compared to those of its respiratory mutants cytB and cydB, and the effects of the ATPase inhibitor DCCD on growth and intracellular ATP concentration were studied. The effects of the ATPase inhibitor DCCD on growth and intracellular ATP concentration strongly indicated that the apparent lack of oxidative phosphorylation in aerobically growing Z. mobilis culture might be caused by the ATP hydrolyzing activity of the H(+) -dependent ATPase in all analyzed strains. Aerobic growth yields of the mutants, and their capacity of oxidative ATP synthesis with ethanol we…

ATP synthasebiologyCellular respirationATPaseGeneral MedicineOxidative phosphorylationbiology.organism_classificationApplied Microbiology and BiotechnologyZymomonas mobilisElectron transport chainBiochemistrybiology.proteinPhosphorylationIntracellularJournal of Basic Microbiology
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Respiratory behaviour of a Zymomonas mobilis adhB::kan(r) mutant supports the hypothesis of two alcohol dehydrogenase isoenzymes catalysing opposite …

2006

AbstractPerturbation of the aerobic steady-state in a chemostat culture of the ethanol-producing bacterium Zymomonas mobilis with a small pulse of ethanol causes a burst of ethanol oxidation, although the reactant ratio of the alcohol dehydrogenase (ADH) reaction ([NADH][acetaldehyde][H+])/([ethanol][NAD+]) remains above the Keq value. Simultaneous catalysis of ethanol synthesis and oxidation by the two ADH isoenzymes, residing in different redox microenvironments, has been proposed previously. In the present study, this hypothesis is verified by construction of an ADH-deficient strain and by demonstration that it lacks the oxidative burst in response to perturbation of its aerobic steady-s…

Kanamycin ResistanceBiophysicsMetabolic channellingChemostatBiochemistryRedoxZymomonas mobilisModels BiologicalCatalysischemistry.chemical_compoundContinuous cultureStructural BiologyGeneticsEthanol metabolismMolecular BiologyAlcohol dehydrogenaseZymomonasEthanolbiologyEthanolChemistryRespirationZymomonas mobilisAcetaldehydeAlcohol DehydrogenaseCell Biologybiology.organism_classificationAerobiosisIsoenzymesKineticsBiochemistrybiology.proteinMutant ProteinsNAD+ kinaseFEBS letters
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NADH dehydrogenase deficiency results in low respiration rate and improved aerobic growth of Zymomonas mobilis.

2008

The respiratory chain of the ethanol-producing bacterium Zymomonas mobilis is able to oxidize both species of nicotinamide cofactors, NADH and NADPH. A mutant strain with a chloramphenicol-resistance determinant inserted in ndh (encoding an NADH : CoQ oxidoreductase of type II) lacked the membrane NADH and NADPH oxidase activities, while its respiratory d-lactate oxidase activity was increased. Cells of the mutant strain showed a very low respiration rate with glucose and no respiration with ethanol. The aerobic growth rate of the mutant was elevated; exponential growth persisted longer, resulting in higher biomass densities. For the parent strain a similar effect of aerobic growth stimulat…

Respiratory chainDehydrogenaseAcetaldehydeMicrobiologyZymomonas mobilisMixed Function Oxygenaseschemistry.chemical_compoundBacterial ProteinsOxidoreductaseRespirationBiomasschemistry.chemical_classificationOxidase testZymomonasbiologyEthanolCell MembraneAcetaldehydeNADH Dehydrogenasebiology.organism_classificationNADAerobiosisOxygenMutagenesis InsertionalGlucosechemistryBiochemistryRespiration rateOxidation-ReductionGene DeletionNADPMicrobiology (Reading, England)
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Respiratory type II NAD(P)H dehydrogenase of Zymomonas mobilis with altered cofactor specificity

2014

NAD(P)H dehydrogenasebiologyBiochemistryChemistryBiophysicsbiology.proteinCell BiologyRespiratory systembiology.organism_classificationBiochemistryZymomonas mobilisCofactorBiochimica et Biophysica Acta (BBA) - Bioenergetics
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Syntrophy of Crypthecodinium cohnii and immobilized Zymomonas mobilis for docosahexaenoic acid production from sucrose-containing substrates

2021

Marine heterotrophic dinoflagellate Crypthecodinium cohnii is an aerobic oleaginous microorganism that accumulates intracellular lipid with high content of 4,7,10,13,16,19-docosahexaenoic acid (DHA), a polyunsaturated ω-3 (22:6) fatty acid with multiple health benefits. C. cohnii can grow on glucose and ethanol, but not on sucrose or fructose. For conversion of sucrose-containing renewables to C. cohnii DHA, we investigated a syntrophic process, involving immobilized cells of ethanologenic bacterium Zymomonas mobilis for fermenting sucrose to ethanol. The non-respiring, NADH dehydrogenase-deficient Z. mobilis strain Zm6-ndh, with high ethanol yield both under anaerobic and aerobic condition…

chemistry.chemical_classificationSucroseZymomonasSucroseDocosahexaenoic AcidsbiologyFatty acidLevansucraseBioengineeringFructoseGeneral MedicineCrypthecodinium cohniibiology.organism_classificationApplied Microbiology and BiotechnologyZymomonas mobilischemistry.chemical_compoundchemistrySyntrophyFermentationDinoflagellidaFermentationFood scienceBiotechnologyJournal of Biotechnology
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Structure of the Zymomonas mobilis respiratory chain: oxygen affinity of electron transport and the role of cytochrome c peroxidase

2014

The genome of the ethanol-producing bacterium Zymomonas mobilis encodes a bd-type terminal oxidase, cytochrome bc 1 complex and several c-type cytochromes, yet lacks sequences homologous to any of the known bacterial cytochrome c oxidase genes. Recently, it was suggested that a putative respiratory cytochrome c peroxidase, receiving electrons from the cytochrome bc 1 complex via cytochrome c 552, might function as a peroxidase and/or an alternative oxidase. The present study was designed to test this hypothesis, by construction of a cytochrome c peroxidase mutant (Zm6-perC), and comparison of its properties with those of a mutant defective in the cytochrome b subunit of the bc 1 complex (Zm…

ZymomonasbiologyCytochrome bc1Cytochrome c peroxidaseCytochrome cCytochrome dCytochrome-c PeroxidaseMicrobiologyMolecular biologyStandardElectron TransportOxygenBiochemistryCytochrome C1Coenzyme Q – cytochrome c reductasebiology.proteinCytochrome c oxidaseOxidoreductasesPhysiology and BiochemistryGene DeletionPeroxidaseMicrobiology
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Ethanol cycle in an ethanologenic bacterium

2002

AbstractA novel redox cycle is suggested, performing interconversion between acetaldehyde and ethanol in aerobically growing ethanologenic bacterium Zymomonas mobilis. It is formed by the two alcohol dehydrogenase (ADH) isoenzymes simultaneously catalyzing opposite reactions. ADH I is catalyzing acetaldehyde reduction. The local reactant ratio at its active site probably is shifted towards ethanol synthesis due to direct channeling of NADH from glycolysis. ADH II is oxidizing ethanol. The net result of the cycle operation is NADH shuttling from glycolysis to the membrane respiratory chain, and ensuring flexible distribution of reducing equivalents between the ADH reaction and respiration.

NADH channelingBiophysicsRespiratory chainBiochemistryZymomonas mobilischemistry.chemical_compoundStructural BiologyGeneticsGlycolysisEthanol metabolismMolecular BiologyAlcohol dehydrogenaseZymomonasEthanolEthanolbiologyFutile cycleRespirationZymomonas mobilisAlcohol dehydrogenaseAcetaldehydeCell BiologyNADbiology.organism_classificationAerobiosisIsoenzymeschemistryBiochemistryFutile cycleChemostatbiology.proteinOxidation-Reductionhormones hormone substitutes and hormone antagonistsFEBS Letters
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Erratum to “electron transport chain in aerobically cultivatedZymomonas mobilis” [FEMS microbiol. lett. 143 (1996) 185–189]

1996

biologyBiochemistryChemistryGeneticsbiology.organism_classificationMolecular BiologyMicrobiologyElectron transport chainZymomonas mobilisFEMS Microbiology Letters
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Membrane D-lactate oxidase in Zymomonas mobilis: evidence for a branched respiratory chain.

1998

Respiratory chain composition of the ethanol-producing bacterium Zymomonas mobilis was studied. Its membrane D-lactate oxidase was characterised. With NADH, but not D-lactate as substrate, a cytochrome o-like component was seen in CO difference spectra. Chlorpromazine specifically inhibited reduction of cytochrome d, while myxothiazol eliminated the cytochrome o-like features in CO difference spectra. It is suggested that electrons from NADH are distributed between branches terminated by the cytochrome o-like component, cytochrome a, and cytochrome d. With D-lactate, electrons are transported to cytochrome a, or an unidentified CN(-)-sensitive oxidase, and cytochrome d.

StereochemistryChlorpromazineMicrobiologyMixed Function OxygenasesElectron Transportchemistry.chemical_compoundOxygen ConsumptionCytochrome C1Multienzyme ComplexesGeneticsCytochrome c oxidaseNADH NADPH OxidoreductasesLactic AcidMolecular BiologyZymomonasbiologyMyxothiazolCytochrome b6f complexCytochrome bCytochrome cCytochrome dNADAerobiosisThiazolesBiochemistrychemistrySpectrophotometryCoenzyme Q – cytochrome c reductasebiology.proteinCytochromesMethacrylatesOxidation-ReductionFEMS microbiology letters
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Translocation of Zymomonas mobilis pyruvate decarboxylase to periplasmic compartment for production of acetaldehyde outside the cytosol

2019

Abstract Acetaldehyde, a valuable commodity chemical, is a volatile inhibitory byproduct of aerobic fermentation in Zymomonas mobilis and in several other microorganisms. Attempting to improve acetaldehyde production by minimizing its contact with the cell interior and facilitating its removal from the culture, we engineered a Z. mobilis strain with acetaldehyde synthesis reaction localized in periplasm. For that, the pyruvate decarboxylase (PDC) was transferred from the cell interior to the periplasmic compartment. This was achieved by the construction of a Z. mobilis Zm6 PDC‐deficient mutant, fusion of PDC with the periplasmic signal sequence of Z. mobilis gluconolactonase, and the follow…

Recombinant Fusion Proteinslcsh:QR1-502macromolecular substancesAcetaldehydeMicrobiologyZymomonas mobilislcsh:Microbiologychemistry.chemical_compoundperiplasmZymomonasbiologypyruvate decarboxylaseZymomonas mobilisAcetaldehydeacetaldehyde productionhemic and immune systemsPeriplasmic spaceCompartment (chemistry)Original Articlesbiology.organism_classificationFusion proteinAerobiosisProtein TransportBiochemistrychemistryMetabolic EngineeringFermentationGluconolactonaseFermentationOriginal ArticlePyruvate decarboxylaseMicrobiologyOpen
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Electron transport chain in aerobically cultivated Zymomonas mobilis

1996

Respiratory chain composition and energy coupling in cytoplasmic membrane of Zymomonas mobilis was shown to depend on culture aeration. Aerobically grown cells contained mainly the non-energy-generating NADH dehydrogenase with kM for NADH 58 mM. In anaerobically cultivated bacteria, the energy-coupling NADH dehydrogenase complex with km for NADH 7 mM predominated. In aerobically cultivated Z. mobilis, CoQ content and absorption peaks of cytochromes at 554–556 nm and 525–528 nm were significantly increased. Energy-coupling site I, linked to the NADH:CoQ oxidoreductase complex, could be eliminated under sulfate-deficient cultivation conditions. For anaerobically grown cells this resulted in l…

Oxidoreductase complexCytochromebiologyNADH dehydrogenaseRespiratory chainOxidative phosphorylationbiology.organism_classificationMicrobiologyElectron transport chainZymomonas mobilisBiochemistryGeneticsbiology.proteinMolecular BiologyNADH dehydrogenase complexFEMS Microbiology Letters
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Cyanide inhibits respiration yet stimulates aerobic growth of Zymomonas mobilis

2000

Potassium cyanide at submillimolar concentrations (20-500 microM) inhibited the high respiration rates of aerobic cultures of Zymomonas mobilis but, remarkably, stimulated culture growth. In batch culture, after an extended lag phase, exponential growth persisted longer, resulting in higher biomass densities. In aerobic chemostat cultures, elevated biomass concentration was observed in the presence of cyanide. This growth stimulation effect is attributed to decreased production of the inhibitory metabolite acetaldehyde at lowered respiration rates, when more reducing equivalents are channelled to alcohol dehydrogenase. Growth in the presence of cyanide did not alter the membrane cytochrome …

ZymomonasMembranesbiologyCellular respirationCyanideRespiratory chainPotassium cyanideAcetaldehydeAcetaldehydeCarbohydrate metabolismbiology.organism_classificationMicrobiologyZymomonas mobilisAerobiosischemistry.chemical_compoundAdenosine TriphosphateGlucoseOxygen ConsumptionchemistryBiochemistryRespirationCytochromesBiomassPotassium CyanideCell DivisionMicrobiology
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The paradoxical cyanide-stimulated respiration of Zymomonas mobilis: cyanide sensitivity of alcohol dehydrogenase (ADH II)

2003

The respiratory inhibitor cyanide stimulates growth of the ethanologenic bacteriumZymomonas mobilis, perhaps by diverting reducing equivalents from respiration to ethanol synthesis, thereby minimizing accumulation of toxic acetaldehyde. This study sought to identify cyanide-sensitive components of respiration. In aerobically grown, permeabilizedZ. mobiliscells, addition of 200 μM cyanide caused gradual inhibition of ADH II, the iron-containing alcohol dehydrogenase isoenzyme, which, in aerobic cultures, might be oxidizing ethanol and supplying NADH to the respiratory chain. In membrane preparations, NADH oxidase was inhibited more rapidly, but to a lesser extent, than ADH II. The time-cours…

ZymomonasCyanidesEthanolbiologyCyanideAlcohol DehydrogenaseAcetaldehydeRespiratory chainbiology.organism_classificationMicrobiologyElectron transport chainZymomonas mobilisAerobiosisElectron TransportKineticschemistry.chemical_compoundchemistryBiochemistryRespirationbiology.proteinEnzyme InhibitorsAlcohol dehydrogenaseMicrobiology
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Effect of ADH II Deficiency on the Intracellular Redox Homeostasis in Zymomonas mobilis

2011

Mutant strain of the facultatively anaerobic, ethanol-producing bacteriumZymomonas mobilis, deficient in the Fe-containing alcohol dehydrogenase isoenzyme (ADH II), showed impaired homeostasis of the intracellular NAD(P)H during transition from anaerobic to aerobic conditions, and also in steady-state continuous cultures at various oxygen supplies. At the same time, ADH II deficiency in aerobically grown cells was accompanied by a threefold increase of catalase activity and by about 50% increase of hydrogen peroxide excretion. It is concluded that ADH II under aerobic conditions functions to maintain intracellular redox homeostasis and to protect the cells from endogenous hydrogen peroxide.

Article Subjectlcsh:MedicineBiologyZymomonas mobilislcsh:TechnologyGeneral Biochemistry Genetics and Molecular Biologychemistry.chemical_compoundOxygen ConsumptionSpecies SpecificityHomeostasisHydrogen peroxidelcsh:ScienceGeneral Environmental ScienceAlcohol dehydrogenaseZymomonaslcsh:Tlcsh:RAlcohol DehydrogenaseHydrogen PeroxideGeneral Medicinebiology.organism_classificationOxygenBiochemistrychemistryCatalasebiology.proteinlcsh:QNAD+ kinaseOxidation-ReductionAnaerobic exerciseNADPHomeostasisIntracellularResearch ArticleThe Scientific World Journal
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The Low Energy-Coupling Respiration in Zymomonas mobilis Accelerates Flux in the Entner-Doudoroff Pathway.

2015

Performing oxidative phosphorylation is the primary role of respiratory chain both in bacteria and eukaryotes. Yet, the branched respiratory chains of prokaryotes contain alternative, low energy-coupling electron pathways, which serve for functions other than oxidative ATP generation (like those of respiratory protection, adaptation to low-oxygen media, redox balancing, etc.), some of which are still poorly understood. We here demonstrate that withdrawal of reducing equivalents by the energetically uncoupled respiratory chain of the bacterium Zymomonas mobilis accelerates its fermentative catabolism, increasing the glucose consumption rate. This is in contrast to what has been observed in o…

Metabolic Processes0301 basic medicineRespiratory chainlcsh:MedicineBiochemistryOxidative PhosphorylationGlucose Metabolismlcsh:ScienceZymomonasMultidisciplinarybiologyOrganic CompoundsSimulation and ModelingMonosaccharidesChemical ReactionsCatabolismAerobiosisEnzymesChemistryBiochemistryPhysical SciencesCarbohydrate MetabolismOxidoreductasesOxidation-ReductionResearch Article030106 microbiologyCarbohydratesAcetaldehydeOxidative phosphorylationResearch and Analysis MethodsZymomonas mobilisElectron Transport03 medical and health sciencesOxidationEntner–Doudoroff pathwayDehydrogenasesOrganic Chemistrylcsh:RChemical CompoundsBiology and Life SciencesProteinsNADbiology.organism_classificationElectron transport chainKineticsGlucoseMetabolismFermentationEnzymologyFermentationlcsh:QFlux (metabolism)BacteriaPLoS ONE
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High aerobic growth with low respiratory rate: The ndh-deficient Zymomonas mobilis

2007

biologyChemistryAerobic growthLow respiratory rateBioengineeringGeneral Medicinebiology.organism_classificationApplied Microbiology and BiotechnologyZymomonas mobilisBiotechnologyMicrobiologyJournal of Biotechnology
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Aerobic catabolism and respiratory lactate bypass in Ndh-negative Zymomonas mobilis

2018

Ability to ferment in the presence of oxygen increases the robustness of bioprocesses and opens opportunity for novel industrial setups. The ethanologenic bacterium Zymomonas mobilis performs rapid and efficient anaerobic ethanol fermentation, yet its respiratory NADH dehydrogenase (Ndh)-deficient strain (ndh-) is known to produce ethanol with high yield also under oxic conditions. Compared to the wild type, it has a lower rate of oxygen consumption, and an increased expression of the respiratory lactate dehydrogenase (Ldh). Here we present a quantitative study of the product spectrum and carbon balance for aerobically growing ndh-. Ldh-deficient and Ldh-overexpressing ndh- strains were con…

0301 basic medicinelcsh:BiotechnologyEndocrinology Diabetes and Metabolism030106 microbiologyBiomedical EngineeringRespiratory chainBioethanolEthanol fermentationZymomonas mobilisArticle03 medical and health scienceschemistry.chemical_compoundlcsh:TP248.13-248.65Lactate dehydrogenaselcsh:QH301-705.5biologyCatabolismZymomonas mobilisNADH dehydrogenaseLactate dehydrogenaseNADH dehydrogenaseMetabolismRespiratory chainbiology.organism_classificationlcsh:Biology (General)chemistryBiochemistryOxidative stressbiology.proteinAnaerobic exerciseMetabolic Engineering Communications
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